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| United States Patent |
5,145,450
|
|
Staudenrausch
, et al.
|
September 8, 1992
|
Method and apparatus for separating a continuous string of sausage meat
into individual sausages
Abstract
In a method and apparatus for making sausages in the form of a continuous
string with subsequent separation thereof into individual sausages or into
groups of interconnected sausages, means are provided for varying the
separating operating in a simple manner according to the length of the
sausage and the number of interconnected sausages in groups thereof
desired, while still ensuring an accurated separating perfomance. In the
spearating operation separator elements are mounted opposite one another
on either side of the string that revolve synchronously in the conveying
direction along respective opposite circular paths, their revolving speed
being variable over the non-operative sector of their revolutions relative
to the operative sector where their speed is compatible with the sausage
conveying speed.
| Inventors:
|
Staudenrausch; Georg (Biberach, DE);
Muller; Gerhard (Schlemmerhofen, DE)
|
| Assignee:
|
Albert Handtmann Maschinenfabrik GmbH & Co. KG (DE)
|
| Appl. No.:
|
648519 |
| Filed:
|
January 30, 1991 |
Foreign Application Priority Data
| Jan 31, 1990[DE] | 9001075[U] |
| Current U.S. Class: |
452/47; 452/30; 452/31; 452/46 |
| Intern'l Class: |
A22B 003/08 |
| Field of Search: |
452/47,48,46,31,30
|
References Cited
U.S. Patent Documents
| 4730367 | Mar., 1988 | Vinokur | 452/47.
|
| Foreign Patent Documents |
| 2214413 | Aug., 1974 | EP.
| |
| 2605745 | Aug., 1977 | EP.
| |
| 3104099 | Sep., 1982 | EP.
| |
| 3323659 | Jan., 1985 | EP.
| |
| 3408859 | Sep., 1985 | EP.
| |
Primary Examiner: Kisliuk; Bruce M.
Assistant Examiner: Cruz; Lawrence
Attorney, Agent or Firm: Finnegan, Henderson, Farabow, Garrett & Dunner
Claims
We claim:
1. A method for separating a continuous sausage strand exiting from a
sausage stuffing machine into individual sausages or groups of
interconnected sausages, comprising discharging continuously a stuffed
sausage strand from a stuffing machine, dividing said strand as it moves
downstream from the machine into a string of interconnected sausages by
periodically twisting the strand about its axis to form constrictions
between the sausages, continuously conveying the thus divided sausage
string at a conveying speed away from said dividing step while preventing
the sausages from being rotated and maintaining them in longitudinal
alignment, separating said string at preselected constrictions between
said sausages with a pair of separator elements that rotate periodically
into cooperation with each other to engage and cut the string, said
elements rotating in synchronism about an axis on either side of the
string in opposite circular paths in the conveying direction, the rotating
speed of the separator elements being variable between an operative speed
compatible with said conveying speed when they are in engagement with the
string and a non-operative speed when they are disengaged from the string
to thereby permit the separation of the string to be adjusted to sausages
or group of sausages of different lengths.
2. The method of claim 1, wherein the sausages are pre-divided by a
squeezing means prior to twisting comprising a pair of cooperating
squeezer elements disposed opposite one another on either side of the
strand that come into squeezing engagement with the strand to pre-divide
it into individual sausages, said squeezer elements rotating in
synchronism in the conveying direction, the rotating speed of said
squeezer elements being variable between a speed compatible with the
conveying speed when they are in engagement with the strand and a speed
when they are disengaged from the strand to thereby permit variations in
the length of the sausages.
3. The method of claim 2, wherein said sausage string is separated into
individual sausages, said separator elements and squeezer elements
revolving at the same speeds.
4. The method of claim 2, wherein said sausage string is separated into
groups of interconnected sausages by reducing the revolving speed of said
separator elements relative to the revolving speed of said squeezer
elements.
5. Apparatus for separating a continuous sausage strand exiting from a
sausage stuffing machine into individual sausages or groups of
interconnected sausages comprising twisting means for rotating said
sausage strand about its axis to divide it into a string of interconnected
sausages separated from each other by a constriction, conveying means
located downstream of the twisting means for conveying the divided sausage
string away from the twisting means while preventing it from being
rotated, separating means adjacent the conveying means for cutting the
divided sausage string at the constrictions into individual sausages or
groups of interconnected sausages, said separating means comprising a pair
of separator arms mounted for rotation in opposite circular paths in the
conveying direction on drive shafts perpendicular to the longitudinal axis
of and on either side of the string and drive means for rotating said arms
in synchronism to periodically bring them into cooperation with each other
and a constriction to cut the string and control means for varying the
rotational speed of the separator arms between an operative speed
compatible with the speed of the conveying means when they are in
engagement with a constriction and a non-operative speed when they are
disengaged from the string to thereby permit adjustment of the cutting
operation of the separator arms to sausages or groups of interconnected
sausages of different lengths.
6. The apparatus of claim 5, including squeezing means downstream of said
twisting means in the conveying direction of the sausage strand for
pre-dividing the strand prior to its twisting, said squeezing means
comprising a pair of squeezer elements mounted for rotation on opposite
sides of the strand that periodically come into engagement with the strand
to pre-divide it and drive means for rotating said squeezer elements in
synchronism, said control means rotating said squeezer elements in
proportion to the rotating speeds of said separator arms.
7. The apparatus of claim 5, in which said drive means for said separator
arms comprises a variable-speed electric motor operatively connected to
said control means and a transmission connected between it and said drive
shafts.
8. The apparatus of claim 6, wherein said squeezer elements rotate on drive
shafts and said drive means for said squeezer elements comprises a
variable-speed electric motor operatively connected to said control means
and a transmission connected between it and said squeezer element drive
shafts.
9. The apparatus of claim 5, wherein said conveying means is a pair of
spaced endless belt conveyor belts and drive means for translating said
belts in the conveying direction in synchronism.
10. The apparatus of claim 9, wherein the drive means for said endless
conveyor belts comprises a variable-speed electric motor operatively
connected to said control means.
11. The apparatus of claim 5, wherein that each separator arm has a cutting
blade on its outer peripheral end, the revolving paths of said blades
overlapping one another when they are in engagement with a constriction in
the string, one of said blades revolving at a offset angle of about
1.degree. relative to the other blade.
12. The apparatus of claim 11, wherein the overlap of said revolving paths
is from about 1 to 2 mm.
13. The apparatus of claim 5, wherein one of said separator arms has a
cutting blade on its outer peripheral end while the other separator arm as
a countersupport including a radially opening recess on its outer
peripheral end for receiving the blade of the other arm.
14. The apparatus of claim 13, wherein the radially opening recess of said
countersupport arm has a slot width of from above 1 to 2 mm.
15. The apparatus of claim 13, wherein said countersupport is of a plastic
material.
16. The apparatus of claim 5, wherein one of said separator arms has a
blade having a cutting edge on its outer peripheral end, while the other
separator arm as a countersupport including a chamfered surface on its
outer peripheral end, the cutting edge of said blade sliding on said
chamfered edge of the other arm in a radial direction during the cutting
operation.
17. The apparatus of claim 16, wherein said blade or said countersupport is
resilient.
18. The apparatus of claim 5, wherein the diameter of the revolving paths
of each separator arm is smaller than 80 mm when the sausage diameter is
in the range of from 13 to 40 mm.
Description
BACKGROUND OF THE INVENTION
This invention relates to a method and apparatus for making sausages in a
continuous string and separating the string into individual sausages or
groups of interconnected sausages.
An apparatus of this type is known from German patent application 31 04
099. In this apparatus, a sausage strand provenient from a stuffing
machine is advanced between two endless belts of a conveyor device.
Secured to each of the endless belts are squeezer elements meeting one
another at the location of the return pulleys to squeeze the sausage
strand at respective locations to form a constriction and thereby
subdivide the strand into a string of interconnected sausages. Disposed
downstream of the conveyor belts is a separating device comprising two
parallel drive shafts mounted at spaced locations on opposite sides of the
sausage strand for synchronous rotation in opposite directions and
disposed substantially perpendicular to the conveying direction of the
sausage string, each drive shaft being provided with two radially
projecting separator arms cooperatively meeting one another for the
separating operation. The separator arms of one drive shaft are provided
with blades, while the separator arms of the other drive shaft are
provided with suitable countersupports. For the separating operation the
cutting edge of a blade approaches the respective countersupport to
thereby cut through the constriction between two sausages. A timing belt
connects the endless belts to the drive gear of one of the drive shafts of
the separating device, the two drive shafts themselves being operatively
interconnected by meshing gears.
In this manner it is ensured that the separator arms revolve in synchronism
with the squeezer elements, so that the separation occurs always at the
constriction between two sausages. The construction of the separating
device in the form of synchronously counterrotating separator arms
provided with blades and countersupports results in the advantage that the
blades and countersupports move at the same speed as the sausage string,
so that the blades and countersupports cooperate with one another in a
meshing engagement with respective constrictions between two sausages.
In apparatus of this type, when it is desired to vary the length of the
sausages or the number of sausages in a group thereof, the mechanical
alterations and adjustments required to achieve this are rather difficult
and onerous.
It is therefore an object of the invention to provide a method and
apparatus which permits sausages or groups of sausages to be accurately
separated irrespective of the length of the sausages, of the number of
interconnected sausages and of the sausage conveying speed, without
requiring any difficult adjustments or modifications.
SUMMARY OF THE INVENTION
This object is attained according to the invention by a method for making
sausages in a continuous string and for separating the string into
individual sausages or groups of interconnected sausages, wherein a
sausage strand is made by a stuffing machine and subsequently divided into
interconnected sausages by a twisting device, the thus divided sausages
being retained against rotation and conveyed on at a determined conveying
speed while being maintained in longitudinal alignment. The interconnected
sausages are then separated by means of separator elements disposed
opposite one another and revolving in synchronism along opposite circular
paths in the conveying direction, the revolving speed of the separator
elements being variable over their non-operative revolution sector while
being adjusted to the sausage conveying speed in the operative engagement
sector.
The method permits both the length of the sausages and the number of
interconnected sausages in a group to be varied rapidly and in a simple
manner without degradation of the accuracy of the sausage separating
operation.
The method may be still further improved by pre-dividing the sausages prior
to the twisting operation by means of squeezer elements mounted for
synchronous and opposite revolution along respective circular paths in the
conveying direction, in a manner similar to the separator elements, with
their revolving speed being variable along their non-operative revolution
sector while being adjusted to the sausage conveying speed at their
operative engagement sector.
In this manner it is possible to separate the sausage string into
individual sausages by causing the separator elements and the squeezer
elements to revolve at the same speed, or to separate the sausage string
into groups of interconnected sausages by reducing the revolving speed of
the separator elements relative to that of the squeezer elements.
BRIEF DESCRIPTION OF THE DRAWINGS
Further characteristics and advantages of the invention will become evident
from the description, an example of which is shown in the drawings,
wherein:
FIG. 1 is a diagrammatic sideview of an apparatus according to the
invention,
FIG. 2 is a diagrammatic top plan view of a separating device,
FIG. 3 shows a pair of the blades of the separating device of FIG. 2 in
meshing cooperation,
FIG. 4 shows a detail of a blade,
FIG. 5 is a top plan view of a modified embodiment of the separating
device,
FIG. 6 shows the cooperation of a blade with a countersupport of the
separating device of FIG. 5,
FIG. 7 shows the meshing engagement of two separator blades with a
constriction between two sausages,
FIG. 8 is a top plan view of another modified embodiment of the separating
device, and
FIG. 9 is a detail of the device of FIG. 8.
DETAILED DESCRIPTION OF THE INVENTION
Depicted in FIG. 1 in dash-dot lines is a sausage stuffing machine 17
operable to produce a continuous sausage strand of a sausage skin filled
with sausage meat in the conventional manner. The thus formed sausage
strand 5 is advanced through the center opening of twisting means
comprising a brake ring 1 adapted to be rotated by a twister drive
transmission 2 so that sausage strand 5 is also rotated or twisted to
divide it into a string of interconnected sausages with twisted ends.
Twister drive transmission 2 is driven by an electric motor 3 the
rotational speed of which is controlled by a control means such as a
conventional electronic or hydraulic control unit 4.
In the embodiment shown, sausage strand 5 first enters squeezing means for
pre-dividing the sausages prior to the twisting operation and disposed
immediately downstream of brake ring 1. The squeezing means comprises two
squeezer units 6 only 1 of which is shown in FIG. 1. The two squeezer
units 6 are connected to an electric motor 7 the rotary speed of which is
also controlled by electronic control unit 4.
Structurally combined with electric motor 7 is a transmission 18 having two
drive shafts 8 only one of which is shown. Each drive shaft 8 carries a
squeezer element 9 fixedly secured thereto in a manner not shown in
detail.
Disposed downstream of the squeezing means is a conveying means comprising
two endless conveyor belts 10. Conveyor belts 10 are guided around return
pulleys 11, respective ones of which act as drive pulleys connected to a
variable-speed electric motor 12 the speed of which is also controlled by
electronic control unit 4.
Conveyor belts 10 revolve in opposite directions to thereby convey the
divided sausages 13 in the direction of arrow 14, conveyor belts 10 being
at the same time effective to prevent sausages 13 from being rotated.
As shown in FIGS. 1 and 2, sausages 13 are then separated by a separating
means or device 25. The drive mechanism of the device comprises two
parallel drive shafts 19 mounted at spaced locations on opposite sides of
the sausage string for synchronous rotation in opposite directions about
respective axes extending perpendicular to the conveying direction of the
sausage string.
In the embodiment shown in FIG. 2, each drive shaft 19 carries two
separator arms 20 and 20' mounted on its end so as to project radially
therefrom in opposite directions. At its free end, each separator arm 20
or 20', respectively, carries a blade 22 having a radially outwards facing
cutting edge 21.
Drive shafts 19 are connected to a transmission 23 structurally combined
with an electric motor 24 the rotational speed of which is again
controlled by electronic control unit 4.
The separating device may thus be of the same construction as the squeezer
units 6. Control unit 4 may be operable to control separating device 25 in
proportion to the operation of squeezer units 6. From FIG. 2 it is evident
that the revolving paths 26 and 27 of blades 22 overlap one another by an
amount of preferably about 1 to 2 mm.
FIG. 3 illustrates the manner in which blades 22 meet in mutual cooperation
at the separation point.
Prior to the separating operation, separator arms 20 and 20' with their
blades 22 are in an angular position relative to one another, with the
ends of blades 22 already aligned with a constriction between two sausages
13 in oblique orientation as shown in FIG. 7.
Shown in FIG. 3 in dash-dotted lines are the successive positions of the
two cooperating blades 22 immediately prior to the separating cut and
subsequent thereto. At the instant of the cutting operation, the two
blades 22 may approach one another to a minimum distance therebetween of
about 0.1 mm, this position being depicted in solid lines. It will be seen
that one of blades 22 is slightly offset relative to the other one, so
that they pass through the cutting position in close succession. In this
position an angle of about 20.degree. formed by the two cutting edges has
been found to be particularly effective.
The cutting edges may be ground to a symmetric shape as illustrated in FIG.
3.
The blades may of course also be ground from only one side as shown by way
of example in FIG. 4.
In the separating device diagrammatically illustrated in FIG. 5, one of the
two drive shafts 19 is again provided with two radially projecting
separator arms 20, 20' with respective blades 22 at diametrally opposite
positions.
The other drive shaft 19 is instead provided with two diametrally opposite
and radially outwards projecting countersupports 28 and 28', the ends of
which are formed with respective recessed rim portions 29 and 29',
respectively, defining a radially outwards opening slot 30 and 30',
respectively.
Slots 30, 30' are preferably of a width of about 1 to 2 mm, and receive
therein the cutting edge 21 of the associated blade 22 to a depth of about
1 mm.
This position of blade 22 and countersupport 28' is diagrammatically
illustrated in solid lines in FIG. 6. Shown in dash-dotted lines in this
figure are the successive positions of a blade 22 and a countersupport 28
prior and subsequent to the cutting operation.
The configuration of countersupports 28, 28' with their recessed rim
portions 29 and 29', respectively, permits the countersupports to be made
of a plastic material.
This possibility is also applicable to separator arms 20.
In the separating device diagrammatically illustrated in FIGS. 8 and 9, one
drive shaft 19 carries at least one separator arm 31 having attached
thereto a blade 32 which may for instance be made of steel strip or a
similarly resiliently flexible material.
As is evident from FIG. 9, blade 32 is ground from one side to form a
cutting edge 35. Mounted on the other drive shaft 19 is at least one
countersupport 33 having a chamfered end face 34. The manner in which
cutting edge 35 of blade 32 cooperates with chamfered end face 34 of
countersupport 33 is illustrated in FIG. 8. In the course of the rotation
indicated by arrows, cutting edge 35 approaches chamfered end face 34 at
the location of a sausage string constriction. At this stage, the
centerlines of separator arm 31 and countersupport 33 form a blunt angle.
As blade 32 and countersupport 33 continue to revolve, cutting edge 35
comes into contact with chamfered end face 34 and slides forwards thereon
until blade 32 is in linear alignment with the centerline of
countersupport 33. The respective intermediate positions are illustrated
by dash-dotted lines in FIG. 8.
At this stage the leaf-spring nature of blade 32 permits cutting edge 35 to
be resiliently held in contact with chamfered end face 34.
The revolving paths of the outer edge of countersupport 33 and blade 35
overlap one another so as to extend by about 0.5 mm to 1.5 mm over the
dash-dotted centerline indicated at 36.
In the embodiment shown, the outer end of countersupport 33 is provided
with another chamfered face 38 opposite chamfered end face 34, resulting
in the formation of an edge 37 which may also act as a cutting edge. On
the other hand, the provision of chamfered face 38 results in the
advantage that the end portions of the sausages are not damaged by their
contact with the countersupport arms.
When making sausages of greater length or groups of interconnected
sausages, it may be advantageous to provide only a single separator arm on
each drive shaft 19, in which case the cooperating separator arms may each
be provided with a cutting blade. Otherwise one arm may carry a cutting
blade, while the other one acts as a countersupport. The described
apparatus operates as follows:
The sausage strand 5 emerging from stuffing machine 17 is entrained in
rotation by brake ring 1, as the latter is rotated by electric motor 3
through transmission 2.
The oppositely revolving squeezer elements 9 come into engagement with
sausage strand 5, their revolving speed being controlled so that their
tangential speed substantially corresponds to the advancing speed of
sausage strand 5 as determined by endless belts 10.
While it is being constricted by squeezer elements 9, sausage strand 5
continues to rotate until the previously twisted leading end of a sausage
13 is gripped between endless belts 10, so that a further constriction is
formed at the trailing end of the sausage. The continued rotation of the
trailing portion of sausage strand 5 will then result in the trailing end
of the sausage being twisted.
The electronic control unit 4 controls the revolving speed of squeezer
elements 9 in accordance with the length of the sausages to be made.
The thus divided, but still interconnected sausages are retained between
endless conveyor belts 10 and fed to separating device 25. The revolving
speed of the separator arms is variable by controlling the rotary speed of
the electric motor 24 of the device by means of electronic control unit 4.
In order to ensure that the separator elements of the separating device,
for instance blades 22, are brought to their cutting position at the exact
location of a selected constriction between adjacent sausages 13, their
operation may be suitably controlled in synchronism with or in proportion
to that of squeezer elements 9. Control unit 4 may also act to control the
revolving speed of separator arms 20 in such a manner that the separation
is performed at each constriction or otherwise after a group of a selected
number of sausages has passed the device. In the latter case, control unit
4 acts to reduce the revolving speed of separator arms 20, possibly down
to zero, during the non-operative part of their revolution.
It is only at the instant of the separating operation or the pre-dividing
operation, respectively, that the revolving speed of separator arms 20 or
squeezer elements 9, respectively, is controlled so as to substantially
correspond to the conveying speed of endless belts 10. This synchronized
operation is already established when the separator arms or squeezer
elements, respectively, are in an oblique position opposite a constriction
between two sausages as illustrated in FIG. 7. At this stage the
centerlines of separator arms 20 enclose an angle of about 90.degree.,
while their blades 22 are received in meshing engagement at the
constriction between two sausages and subsequently revolve in substantial
synchronism with the sausage conveying speed.
In extreme cases, it is also possible to cause the separator arms to move
at an even faster speed than the conveying speed of endless belts over a
selected angular range prior to the separating operation, and to
subsequently reduce their speed.
The length of the separator arms, i.e. the diameter of the revolving path
26 of cutting edges 21, is determined in accordance with the diameter of
the sausages to be separated. When the sausage diameter lies between 13
and 40 mm, a revolving path diameter of about 80 mm or less has been found
very suitable, because it permits the diameter of the sausages being
processed to be varied within a rather wide range. In the case of greater
sausage diameters, the revolving path diameter should be correspondingly
greater. The described apparatus permits a considerably greater number of
sausages or groups of sausages to be processed per time unit than in the
case of conventional separating devices.
The maximum possible separating performance is dependent on the following
parameters:
Length of sausages,
conveyor belt speed,
number of interconnected sausages per group,
interaxial spacing of the separator element shafts,
number of separator elements per shaft (1 or 2),
engagement angle of the separator elements with the sausage string,
maximum admissible radial acceleration or deceleration, respectively.
In this context should be noted that the drive mechanism of endless
conveyor belts 10 comprising electric motor 12 is of course also
controlled by control unit 4, as is the electric motor 3 operating the
twisting gear mechanism 2. In this manner it is possible to program all of
the various movements for optimum synchronization.
Depending on the length of the sausages, the speed of the conveyor belts
and the number of interconnected sausages in each group, the revolution of
the separator elements and squeezer elements, respectively, may be
accelerated or decelerated in their inoperative, disengaged state. In the
case of sausages of greater length or of a greater number of
interconnected sausages in each group, the revolution may even be stopped
for a selected period of time at a neutral position.
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